The paper presents simulation and experimental results of an Electric Controlled Permanent Magnet Synchronous (ECPMS) machine that offers an extended magnetic field control capability. This makes it suitable for battery electric vehicle drives. Rotor, stator and additional direct current supplied coil of the machine have been analyzed in detail. Control and power supply systems of the machine have been presented. Influence of the additional excitation on the machine performance has also been discussed.
Di BarbaP., BonislawskiM., PalkaR., PaplickiP. and WardachM., Design of Hybrid Excited Synchronous Machine for Electrical Vehicles, IEEE Trans. Magn.51(8) Aug. (2015).
2.
Di BarbaP., MognaschiM.E., PalkaR., PaplickiP. and SzkolnyS., Design optimization of a permanent-magnet excited synchronous machine for electrical automobiles, International Journal of Applied Electromagnetics and Mechanics39(1-4) (2012), 889-895.
3.
Ki-ChanK., A Novel Magnetic Flux Weakening Method of Permanent Magnet Synchronous Motor for Electric Vehicles, IEEE Trans. Magn.48(11) (2012), 4042-4045.
4.
MbayedR., VidoL., SalloumG., MonmassonE. and GabsiM., Effect of iron losses on the model and control of a hybrid excitation synchronous generator, IEEE International Electric Machines & Drives Conference, 2011, 971-976.
5.
PaplickiP., WardachM., BonislawskiM. and PalkaR., Simulation and experimental results of hybrid electric machine with a novel flux control strategy, Archives of Electrical Engineering64(1) (2015), 37-51.
6.
PalkaR., Synthesis of magnetic fields by optimization of the shape of areas and source distributions, Electrical Engineering75 (1991), 1-7.
7.
PaplickiP., Optimization of the electrically controlled permanent magnet excited synchronous machine to improve flux control range, Electronika ir electrotechnika,20(10) (2014), 17-22.
8.
PatinN., VidoL., MonmassonE. and LouisJ.-P., Control of a DC generator based on a Hybrid Excitation Synchronous Machine connected to a PWM rectifier, IEEE International Symposium on Industrial Electronics3 (2006), 2229-2234.
9.
PutekP., PaplickiP. and PalkaR., Low cogging torque design of permanent-magnet machine using modified multi-level set method with total variation regularization, IEEE Trans. Magn.50(2) (Feb. 2014).
10.
PutekP., PaplickiP. and PalkaR., Topology optimization of rotor poles in a permanent-magnet machine using level set method and continuum design sensitivity analysis, Compel33(3) (2014), 711-728.
11.
PutekP., SlodičkaM., PaplickiP. and PalkaR., Minimization of cogging torque in permanent magnet machines using the topological gradient and adjoint sensitivity in multi-objective design, International Journal of Applied Electromagnetics and Mechanics39(1-4) (Apr. 2012), 933-940.
12.
SikoraR. and PalkaR., Synthesis of One- and Twodimensional Electrostatic Field, Electrical Engineering64 (1981), 105-108.
13.
TapiaJ.A., LeonardiF. and LipoT.A., Consequent-Pole Permanent-Magnet Machine with Extended Field-Weakening Capability, IEEE Transactions on Industry Applications39 (2003), 1704-1709.
